/* LzmaEnc.c -- LZMA Encoder
   2009-11-24 : Igor Pavlov : Public domain */

#include "Types.h"

/* #define SHOW_STAT */
/* #define SHOW_STAT2 */

#include "LzmaEnc.h"

#include "LzFind.h"
#ifndef _7ZIP_ST
    #include "LzFindMt.h"
#endif

#ifdef SHOW_STAT
static int ttt = 0;
#endif

#define kBlockSizeMax ((1 << LZMA_NUM_BLOCK_SIZE_BITS) - 1)

#define kBlockSize (9 << 10)
#define kUnpackBlockSize (1 << 18)
#define kMatchArraySize (1 << 21)
#define kMatchRecordMaxSize ((LZMA_MATCH_LEN_MAX * 2 + 3) * LZMA_MATCH_LEN_MAX)

#define kNumMaxDirectBits (31)

#define kNumTopBits 24
#define kTopValue ((UInt32)1 << kNumTopBits)

#define kNumBitModelTotalBits 11
#define kBitModelTotal (1 << kNumBitModelTotalBits)
#define kNumMoveBits 5
#define kProbInitValue (kBitModelTotal >> 1)

#define kNumMoveReducingBits 4
#define kNumBitPriceShiftBits 4
#define kBitPrice (1 << kNumBitPriceShiftBits)

void LzmaEncProps_Init(CLzmaEncProps* p)
{
    p->level = 5;
    p->dictSize = p->mc = 0;
    p->lc = p->lp = p->pb = p->algo = p->fb = p->btMode = p->numHashBytes = p->numThreads = -1;
    p->writeEndMark = 0;
}

void LzmaEncProps_Normalize(CLzmaEncProps* p)
{
    int level = p->level;
    if (level < 0) level = 5;
    p->level = level;
    if (p->dictSize == 0) p->dictSize = (level <= 5 ? (1 << (level * 2 + 14)) : (level == 6 ? (1 << 25) : (1 << 26)));
    if (p->lc < 0) p->lc = 3;
    if (p->lp < 0) p->lp = 0;
    if (p->pb < 0) p->pb = 2;
    if (p->algo < 0) p->algo = (level < 5 ? 0 : 1);
    if (p->fb < 0) p->fb = (level < 7 ? 32 : 64);
    if (p->btMode < 0) p->btMode = (p->algo == 0 ? 0 : 1);
    if (p->numHashBytes < 0) p->numHashBytes = 4;
    if (p->mc == 0) p->mc = (16 + (p->fb >> 1)) >> (p->btMode ? 0 : 1);
    if (p->numThreads < 0)
        p->numThreads =
            #ifndef _7ZIP_ST
                ((p->btMode && p->algo) ? 2 : 1);
            #else
            1;
    #endif
}

UInt32 LzmaEncProps_GetDictSize(const CLzmaEncProps* props2)
{
    CLzmaEncProps props = *props2;
    LzmaEncProps_Normalize(&props);
    return props.dictSize;
}

/* #define LZMA_LOG_BSR */
/* Define it for Intel's CPU */


#ifdef LZMA_LOG_BSR

    #define kDicLogSizeMaxCompress 30

    #define BSR2_RET(pos, res) { unsigned long i; _BitScanReverse(&i, (pos)); res = (i + i) + ((pos >> (i - 1)) & 1); }

UInt32 GetPosSlot1(UInt32 pos)
{
    UInt32 res;
    BSR2_RET(pos, res);
    return res;
}
    #define GetPosSlot2(pos, res) { BSR2_RET(pos, res); }
    #define GetPosSlot(pos, res) { if (pos < 2) res = pos;else BSR2_RET(pos, res);}

#else

    #define kNumLogBits (9 + (int)sizeof(size_t) / 2)
    #define kDicLogSizeMaxCompress ((kNumLogBits - 1) * 2 + 7)

void LzmaEnc_FastPosInit(Byte* g_FastPos)
{
    int c = 2, slotFast;
    g_FastPos[0] = 0;
    g_FastPos[1] = 1;

    for (slotFast = 2; slotFast < kNumLogBits * 2; slotFast++)
    {
        UInt32 k = (1 << ((slotFast >> 1) - 1));
        UInt32 j;
        for (j = 0; j < k; j++, c++)
            g_FastPos[c] = (Byte)slotFast;
    }
}

    #define BSR2_RET(pos, res) { UInt32 i = 6 + ((kNumLogBits - 1) & \
                                                 (0 - (((((UInt32)1 << (kNumLogBits + 6)) - 1) - pos) >> 31))); \
                                 res = p->g_FastPos[pos >> i] + (i * 2); }
/*
 #define BSR2_RET(pos, res) { res = (pos < (1 << (kNumLogBits + 6))) ? \
   p->g_FastPos[pos >> 6] + 12 : \
   p->g_FastPos[pos >> (6 + kNumLogBits - 1)] + (6 + (kNumLogBits - 1)) * 2; }
 */

    #define GetPosSlot1(pos) p->g_FastPos[pos]
    #define GetPosSlot2(pos, res) { BSR2_RET(pos, res); }
    #define GetPosSlot(pos, res) { if (pos < kNumFullDistances) res = p->g_FastPos[pos];else BSR2_RET(pos, res);}

#endif


#define LZMA_NUM_REPS 4

typedef unsigned CState;

typedef struct
{
    UInt32 price;

    CState state;
    int prev1IsChar;
    int prev2;

    UInt32 posPrev2;
    UInt32 backPrev2;

    UInt32 posPrev;
    UInt32 backPrev;
    UInt32 backs[LZMA_NUM_REPS];
} COptimal;

#define kNumOpts (1 << 12)

#define kNumLenToPosStates 4
#define kNumPosSlotBits 6
#define kDicLogSizeMin 0
#define kDicLogSizeMax 32
#define kDistTableSizeMax (kDicLogSizeMax * 2)


#define kNumAlignBits 4
#define kAlignTableSize (1 << kNumAlignBits)
#define kAlignMask (kAlignTableSize - 1)

#define kStartPosModelIndex 4
#define kEndPosModelIndex 14
#define kNumPosModels (kEndPosModelIndex - kStartPosModelIndex)

#define kNumFullDistances (1 << (kEndPosModelIndex >> 1))

#ifdef _LZMA_PROB32
    #define CLzmaProb UInt32
#else
    #define CLzmaProb UInt16
#endif

#define LZMA_PB_MAX 4
#define LZMA_LC_MAX 8
#define LZMA_LP_MAX 4

#define LZMA_NUM_PB_STATES_MAX (1 << LZMA_PB_MAX)


#define kLenNumLowBits 3
#define kLenNumLowSymbols (1 << kLenNumLowBits)
#define kLenNumMidBits 3
#define kLenNumMidSymbols (1 << kLenNumMidBits)
#define kLenNumHighBits 8
#define kLenNumHighSymbols (1 << kLenNumHighBits)

#define kLenNumSymbolsTotal (kLenNumLowSymbols + kLenNumMidSymbols + kLenNumHighSymbols)

#define LZMA_MATCH_LEN_MIN 2
#define LZMA_MATCH_LEN_MAX (LZMA_MATCH_LEN_MIN + kLenNumSymbolsTotal - 1)

#define kNumStates 12

typedef struct
{
    CLzmaProb choice;
    CLzmaProb choice2;
    CLzmaProb low[LZMA_NUM_PB_STATES_MAX << kLenNumLowBits];
    CLzmaProb mid[LZMA_NUM_PB_STATES_MAX << kLenNumMidBits];
    CLzmaProb high[kLenNumHighSymbols];
} CLenEnc;

typedef struct
{
    CLenEnc p;
    UInt32 prices[LZMA_NUM_PB_STATES_MAX][kLenNumSymbolsTotal];
    UInt32 tableSize;
    UInt32 counters[LZMA_NUM_PB_STATES_MAX];
} CLenPriceEnc;

typedef struct
{
    UInt32 range;
    Byte cache;
    UInt64 low;
    UInt64 cacheSize;
    Byte* buf;
    Byte* bufLim;
    Byte* bufBase;
    ISeqOutStream* outStream;
    UInt64 processed;
    SRes res;
} CRangeEnc;

typedef struct
{
    CLzmaProb* litProbs;

    CLzmaProb isMatch[kNumStates][LZMA_NUM_PB_STATES_MAX];
    CLzmaProb isRep[kNumStates];
    CLzmaProb isRepG0[kNumStates];
    CLzmaProb isRepG1[kNumStates];
    CLzmaProb isRepG2[kNumStates];
    CLzmaProb isRep0Long[kNumStates][LZMA_NUM_PB_STATES_MAX];

    CLzmaProb posSlotEncoder[kNumLenToPosStates][1 << kNumPosSlotBits];
    CLzmaProb posEncoders[kNumFullDistances - kEndPosModelIndex];
    CLzmaProb posAlignEncoder[1 << kNumAlignBits];

    CLenPriceEnc lenEnc;
    CLenPriceEnc repLenEnc;

    UInt32 reps[LZMA_NUM_REPS];
    UInt32 state;
} CSaveState;

typedef struct
{
    IMatchFinder matchFinder;
    void* matchFinderObj;

    #ifndef _7ZIP_ST
    Bool mtMode;
    CMatchFinderMt matchFinderMt;
    #endif

    CMatchFinder matchFinderBase;

    #ifndef _7ZIP_ST
    Byte pad[128];
    #endif

    UInt32 optimumEndIndex;
    UInt32 optimumCurrentIndex;

    UInt32 longestMatchLength;
    UInt32 numPairs;
    UInt32 numAvail;
    COptimal opt[kNumOpts];

    #ifndef LZMA_LOG_BSR
    Byte g_FastPos[1 << kNumLogBits];
    #endif

    UInt32 ProbPrices[kBitModelTotal >> kNumMoveReducingBits];
    UInt32 matches[LZMA_MATCH_LEN_MAX * 2 + 2 + 1];
    UInt32 numFastBytes;
    UInt32 additionalOffset;
    UInt32 reps[LZMA_NUM_REPS];
    UInt32 state;

    UInt32 posSlotPrices[kNumLenToPosStates][kDistTableSizeMax];
    UInt32 distancesPrices[kNumLenToPosStates][kNumFullDistances];
    UInt32 alignPrices[kAlignTableSize];
    UInt32 alignPriceCount;

    UInt32 distTableSize;

    unsigned lc, lp, pb;
    unsigned lpMask, pbMask;

    CLzmaProb* litProbs;

    CLzmaProb isMatch[kNumStates][LZMA_NUM_PB_STATES_MAX];
    CLzmaProb isRep[kNumStates];
    CLzmaProb isRepG0[kNumStates];
    CLzmaProb isRepG1[kNumStates];
    CLzmaProb isRepG2[kNumStates];
    CLzmaProb isRep0Long[kNumStates][LZMA_NUM_PB_STATES_MAX];

    CLzmaProb posSlotEncoder[kNumLenToPosStates][1 << kNumPosSlotBits];
    CLzmaProb posEncoders[kNumFullDistances - kEndPosModelIndex];
    CLzmaProb posAlignEncoder[1 << kNumAlignBits];

    CLenPriceEnc lenEnc;
    CLenPriceEnc repLenEnc;

    unsigned lclp;

    Bool fastMode;

    CRangeEnc rc;

    Bool writeEndMark;
    UInt64 nowPos64;
    UInt32 matchPriceCount;
    Bool finished;
    Bool multiThread;

    SRes result;
    UInt32 dictSize;
    UInt32 matchFinderCycles;

    int needInit;

    CSaveState saveState;
} CLzmaEnc;

void LzmaEnc_SaveState(CLzmaEncHandle pp)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    CSaveState* dest = &p->saveState;
    int i;
    dest->lenEnc = p->lenEnc;
    dest->repLenEnc = p->repLenEnc;
    dest->state = p->state;

    for (i = 0; i < kNumStates; i++)
    {
        memcpy(dest->isMatch[i], p->isMatch[i], sizeof(p->isMatch[i]));
        memcpy(dest->isRep0Long[i], p->isRep0Long[i], sizeof(p->isRep0Long[i]));
    }
    for (i = 0; i < kNumLenToPosStates; i++)
        memcpy(dest->posSlotEncoder[i], p->posSlotEncoder[i], sizeof(p->posSlotEncoder[i]));
    memcpy(dest->isRep, p->isRep, sizeof(p->isRep));
    memcpy(dest->isRepG0, p->isRepG0, sizeof(p->isRepG0));
    memcpy(dest->isRepG1, p->isRepG1, sizeof(p->isRepG1));
    memcpy(dest->isRepG2, p->isRepG2, sizeof(p->isRepG2));
    memcpy(dest->posEncoders, p->posEncoders, sizeof(p->posEncoders));
    memcpy(dest->posAlignEncoder, p->posAlignEncoder, sizeof(p->posAlignEncoder));
    memcpy(dest->reps, p->reps, sizeof(p->reps));
    memcpy(dest->litProbs, p->litProbs, (0x300 << p->lclp) * sizeof(CLzmaProb));
}

void LzmaEnc_RestoreState(CLzmaEncHandle pp)
{
    CLzmaEnc* dest = (CLzmaEnc*)pp;
    const CSaveState* p = &dest->saveState;
    int i;
    dest->lenEnc = p->lenEnc;
    dest->repLenEnc = p->repLenEnc;
    dest->state = p->state;

    for (i = 0; i < kNumStates; i++)
    {
        memcpy(dest->isMatch[i], p->isMatch[i], sizeof(p->isMatch[i]));
        memcpy(dest->isRep0Long[i], p->isRep0Long[i], sizeof(p->isRep0Long[i]));
    }
    for (i = 0; i < kNumLenToPosStates; i++)
        memcpy(dest->posSlotEncoder[i], p->posSlotEncoder[i], sizeof(p->posSlotEncoder[i]));
    memcpy(dest->isRep, p->isRep, sizeof(p->isRep));
    memcpy(dest->isRepG0, p->isRepG0, sizeof(p->isRepG0));
    memcpy(dest->isRepG1, p->isRepG1, sizeof(p->isRepG1));
    memcpy(dest->isRepG2, p->isRepG2, sizeof(p->isRepG2));
    memcpy(dest->posEncoders, p->posEncoders, sizeof(p->posEncoders));
    memcpy(dest->posAlignEncoder, p->posAlignEncoder, sizeof(p->posAlignEncoder));
    memcpy(dest->reps, p->reps, sizeof(p->reps));
    memcpy(dest->litProbs, p->litProbs, (0x300 << dest->lclp) * sizeof(CLzmaProb));
}

SRes LzmaEnc_SetProps(CLzmaEncHandle pp, const CLzmaEncProps* props2)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    CLzmaEncProps props = *props2;
    LzmaEncProps_Normalize(&props);

    if (props.lc > LZMA_LC_MAX || props.lp > LZMA_LP_MAX || props.pb > LZMA_PB_MAX ||
        props.dictSize > (1 << kDicLogSizeMaxCompress) || props.dictSize > (1 << 30))
        return SZ_ERROR_PARAM;
    p->dictSize = props.dictSize;
    p->matchFinderCycles = props.mc;
    {
        unsigned fb = props.fb;
        if (fb < 5)
            fb = 5;
        if (fb > LZMA_MATCH_LEN_MAX)
            fb = LZMA_MATCH_LEN_MAX;
        p->numFastBytes = fb;
    }
    p->lc = props.lc;
    p->lp = props.lp;
    p->pb = props.pb;
    p->fastMode = (props.algo == 0);
    p->matchFinderBase.btMode = props.btMode;
    {
        UInt32 numHashBytes = 4;
        if (props.btMode)
        {
            if (props.numHashBytes < 2)
                numHashBytes = 2;
            else if (props.numHashBytes < 4)
                numHashBytes = props.numHashBytes;
        }
        p->matchFinderBase.numHashBytes = numHashBytes;
    }

    p->matchFinderBase.cutValue = props.mc;

    p->writeEndMark = props.writeEndMark;

    #ifndef _7ZIP_ST
    /*
       if (newMultiThread != _multiThread)
       {
       ReleaseMatchFinder();
       _multiThread = newMultiThread;
       }
     */
    p->multiThread = (props.numThreads > 1);
    #endif

    return SZ_OK;
}

static const int kLiteralNextStates[kNumStates] = { 0, 0, 0, 0, 1, 2, 3, 4, 5, 6, 4, 5 };
static const int kMatchNextStates[kNumStates] = { 7, 7, 7, 7, 7, 7, 7, 10, 10, 10, 10, 10 };
static const int kRepNextStates[kNumStates] = { 8, 8, 8, 8, 8, 8, 8, 11, 11, 11, 11, 11 };
static const int kShortRepNextStates[kNumStates] = { 9, 9, 9, 9, 9, 9, 9, 11, 11, 11, 11, 11 };

#define IsCharState(s) ((s) < 7)

#define GetLenToPosState(len) (((len) < kNumLenToPosStates + 1) ? (len) - 2 : kNumLenToPosStates - 1)

#define kInfinityPrice (1 << 30)

static void RangeEnc_Construct(CRangeEnc* p)
{
    p->outStream = 0;
    p->bufBase = 0;
}

#define RangeEnc_GetProcessed(p) ((p)->processed + ((p)->buf - (p)->bufBase) + (p)->cacheSize)

#define RC_BUF_SIZE (1 << 16)
static int RangeEnc_Alloc(CRangeEnc* p, ISzAlloc* alloc)
{
    if (p->bufBase == 0)
    {
        p->bufBase = (Byte*)alloc->Alloc(alloc, RC_BUF_SIZE);
        if (p->bufBase == 0)
            return 0;
        p->bufLim = p->bufBase + RC_BUF_SIZE;
    }
    return 1;
}

static void RangeEnc_Free(CRangeEnc* p, ISzAlloc* alloc)
{
    alloc->Free(alloc, p->bufBase);
    p->bufBase = 0;
}

static void RangeEnc_Init(CRangeEnc* p)
{
    /* Stream.Init(); */
    p->low = 0;
    p->range = 0xFFFFFFFF;
    p->cacheSize = 1;
    p->cache = 0;

    p->buf = p->bufBase;

    p->processed = 0;
    p->res = SZ_OK;
}

static void RangeEnc_FlushStream(CRangeEnc* p)
{
    size_t num;
    if (p->res != SZ_OK)
        return;
    num = p->buf - p->bufBase;
    if (num != p->outStream->Write(p->outStream, p->bufBase, num))
        p->res = SZ_ERROR_WRITE;
    p->processed += num;
    p->buf = p->bufBase;
}

static void MY_FAST_CALL RangeEnc_ShiftLow(CRangeEnc* p)
{
    if ((UInt32)p->low < (UInt32)0xFF000000 || (int)(p->low >> 32) != 0)
    {
        Byte temp = p->cache;
        do
        {
            Byte* buf = p->buf;
            *buf++ = (Byte)(temp + (Byte)(p->low >> 32));
            p->buf = buf;
            if (buf == p->bufLim)
                RangeEnc_FlushStream(p);
            temp = 0xFF;
        }
        while (--p->cacheSize != 0);
        p->cache = (Byte)((UInt32)p->low >> 24);
    }
    p->cacheSize++;
    p->low = (UInt32)p->low << 8;
}

static void RangeEnc_FlushData(CRangeEnc* p)
{
    int i;
    for (i = 0; i < 5; i++)
        RangeEnc_ShiftLow(p);
}

static void RangeEnc_EncodeDirectBits(CRangeEnc* p, UInt32 value, int numBits)
{
    do
    {
        p->range >>= 1;
        p->low += p->range & (0 - ((value >> --numBits) & 1));
        if (p->range < kTopValue)
        {
            p->range <<= 8;
            RangeEnc_ShiftLow(p);
        }
    }
    while (numBits != 0);
}

static void RangeEnc_EncodeBit(CRangeEnc* p, CLzmaProb* prob, UInt32 symbol)
{
    UInt32 ttt = *prob;
    UInt32 newBound = (p->range >> kNumBitModelTotalBits) * ttt;
    if (symbol == 0)
    {
        p->range = newBound;
        ttt += (kBitModelTotal - ttt) >> kNumMoveBits;
    }
    else
    {
        p->low += newBound;
        p->range -= newBound;
        ttt -= ttt >> kNumMoveBits;
    }
    *prob = (CLzmaProb)ttt;
    if (p->range < kTopValue)
    {
        p->range <<= 8;
        RangeEnc_ShiftLow(p);
    }
}

static void LitEnc_Encode(CRangeEnc* p, CLzmaProb* probs, UInt32 symbol)
{
    symbol |= 0x100;
    do
    {
        RangeEnc_EncodeBit(p, probs + (symbol >> 8), (symbol >> 7) & 1);
        symbol <<= 1;
    }
    while (symbol < 0x10000);
}

static void LitEnc_EncodeMatched(CRangeEnc* p, CLzmaProb* probs, UInt32 symbol, UInt32 matchByte)
{
    UInt32 offs = 0x100;
    symbol |= 0x100;
    do
    {
        matchByte <<= 1;
        RangeEnc_EncodeBit(p, probs + (offs + (matchByte & offs) + (symbol >> 8)), (symbol >> 7) & 1);
        symbol <<= 1;
        offs &= ~(matchByte ^ symbol);
    }
    while (symbol < 0x10000);
}

void LzmaEnc_InitPriceTables(UInt32* ProbPrices)
{
    UInt32 i;
    for (i = (1 << kNumMoveReducingBits) / 2; i < kBitModelTotal; i += (1 << kNumMoveReducingBits))
    {
        const int kCyclesBits = kNumBitPriceShiftBits;
        UInt32 w = i;
        UInt32 bitCount = 0;
        int j;
        for (j = 0; j < kCyclesBits; j++)
        {
            w = w * w;
            bitCount <<= 1;
            while (w >= ((UInt32)1 << 16))
            {
                w >>= 1;
                bitCount++;
            }
        }
        ProbPrices[i >> kNumMoveReducingBits] = ((kNumBitModelTotalBits << kCyclesBits) - 15 - bitCount);
    }
}


#define GET_PRICE(prob, symbol) \
    p->ProbPrices[((prob) ^ (((-(int)(symbol))) & (kBitModelTotal - 1))) >> kNumMoveReducingBits];

#define GET_PRICEa(prob, symbol) \
    ProbPrices[((prob) ^ ((-((int)(symbol))) & (kBitModelTotal - 1))) >> kNumMoveReducingBits];

#define GET_PRICE_0(prob) p->ProbPrices[(prob) >> kNumMoveReducingBits]
#define GET_PRICE_1(prob) p->ProbPrices[((prob) ^ (kBitModelTotal - 1)) >> kNumMoveReducingBits]

#define GET_PRICE_0a(prob) ProbPrices[(prob) >> kNumMoveReducingBits]
#define GET_PRICE_1a(prob) ProbPrices[((prob) ^ (kBitModelTotal - 1)) >> kNumMoveReducingBits]

static UInt32 LitEnc_GetPrice(const CLzmaProb* probs, UInt32 symbol, UInt32* ProbPrices)
{
    UInt32 price = 0;
    symbol |= 0x100;
    do
    {
        price += GET_PRICEa(probs[symbol >> 8], (symbol >> 7) & 1);
        symbol <<= 1;
    }
    while (symbol < 0x10000);
    return price;
}

static UInt32 LitEnc_GetPriceMatched(const CLzmaProb* probs, UInt32 symbol, UInt32 matchByte, UInt32* ProbPrices)
{
    UInt32 price = 0;
    UInt32 offs = 0x100;
    symbol |= 0x100;
    do
    {
        matchByte <<= 1;
        price += GET_PRICEa(probs[offs + (matchByte & offs) + (symbol >> 8)], (symbol >> 7) & 1);
        symbol <<= 1;
        offs &= ~(matchByte ^ symbol);
    }
    while (symbol < 0x10000);
    return price;
}


static void RcTree_Encode(CRangeEnc* rc, CLzmaProb* probs, int numBitLevels, UInt32 symbol)
{
    UInt32 m = 1;
    int i;
    for (i = numBitLevels; i != 0;)
    {
        UInt32 bit;
        i--;
        bit = (symbol >> i) & 1;
        RangeEnc_EncodeBit(rc, probs + m, bit);
        m = (m << 1) | bit;
    }
}

static void RcTree_ReverseEncode(CRangeEnc* rc, CLzmaProb* probs, int numBitLevels, UInt32 symbol)
{
    UInt32 m = 1;
    int i;
    for (i = 0; i < numBitLevels; i++)
    {
        UInt32 bit = symbol & 1;
        RangeEnc_EncodeBit(rc, probs + m, bit);
        m = (m << 1) | bit;
        symbol >>= 1;
    }
}

static UInt32 RcTree_GetPrice(const CLzmaProb* probs, int numBitLevels, UInt32 symbol, UInt32* ProbPrices)
{
    UInt32 price = 0;
    symbol |= (1 << numBitLevels);
    while (symbol != 1)
    {
        price += GET_PRICEa(probs[symbol >> 1], symbol & 1);
        symbol >>= 1;
    }
    return price;
}

static UInt32 RcTree_ReverseGetPrice(const CLzmaProb* probs, int numBitLevels, UInt32 symbol, UInt32* ProbPrices)
{
    UInt32 price = 0;
    UInt32 m = 1;
    int i;
    for (i = numBitLevels; i != 0; i--)
    {
        UInt32 bit = symbol & 1;
        symbol >>= 1;
        price += GET_PRICEa(probs[m], bit);
        m = (m << 1) | bit;
    }
    return price;
}


static void LenEnc_Init(CLenEnc* p)
{
    unsigned i;
    p->choice = p->choice2 = kProbInitValue;
    for (i = 0; i < (LZMA_NUM_PB_STATES_MAX << kLenNumLowBits); i++)
        p->low[i] = kProbInitValue;
    for (i = 0; i < (LZMA_NUM_PB_STATES_MAX << kLenNumMidBits); i++)
        p->mid[i] = kProbInitValue;
    for (i = 0; i < kLenNumHighSymbols; i++)
        p->high[i] = kProbInitValue;
}

static void LenEnc_Encode(CLenEnc* p, CRangeEnc* rc, UInt32 symbol, UInt32 posState)
{
    if (symbol < kLenNumLowSymbols)
    {
        RangeEnc_EncodeBit(rc, &p->choice, 0);
        RcTree_Encode(rc, p->low + (posState << kLenNumLowBits), kLenNumLowBits, symbol);
    }
    else
    {
        RangeEnc_EncodeBit(rc, &p->choice, 1);
        if (symbol < kLenNumLowSymbols + kLenNumMidSymbols)
        {
            RangeEnc_EncodeBit(rc, &p->choice2, 0);
            RcTree_Encode(rc, p->mid + (posState << kLenNumMidBits), kLenNumMidBits, symbol - kLenNumLowSymbols);
        }
        else
        {
            RangeEnc_EncodeBit(rc, &p->choice2, 1);
            RcTree_Encode(rc, p->high, kLenNumHighBits, symbol - kLenNumLowSymbols - kLenNumMidSymbols);
        }
    }
}

static void LenEnc_SetPrices(CLenEnc* p, UInt32 posState, UInt32 numSymbols, UInt32* prices, UInt32* ProbPrices)
{
    UInt32 a0 = GET_PRICE_0a(p->choice);
    UInt32 a1 = GET_PRICE_1a(p->choice);
    UInt32 b0 = a1 + GET_PRICE_0a(p->choice2);
    UInt32 b1 = a1 + GET_PRICE_1a(p->choice2);
    UInt32 i = 0;
    for (i = 0; i < kLenNumLowSymbols; i++)
    {
        if (i >= numSymbols)
            return;
        prices[i] = a0 + RcTree_GetPrice(p->low + (posState << kLenNumLowBits), kLenNumLowBits, i, ProbPrices);
    }
    for (; i < kLenNumLowSymbols + kLenNumMidSymbols; i++)
    {
        if (i >= numSymbols)
            return;
        prices[i] = b0 + RcTree_GetPrice(p->mid + (posState << kLenNumMidBits), kLenNumMidBits, i - kLenNumLowSymbols, ProbPrices);
    }
    for (; i < numSymbols; i++)
        prices[i] = b1 + RcTree_GetPrice(p->high, kLenNumHighBits, i - kLenNumLowSymbols - kLenNumMidSymbols, ProbPrices);
}

static void MY_FAST_CALL LenPriceEnc_UpdateTable(CLenPriceEnc* p, UInt32 posState, UInt32* ProbPrices)
{
    LenEnc_SetPrices(&p->p, posState, p->tableSize, p->prices[posState], ProbPrices);
    p->counters[posState] = p->tableSize;
}

static void LenPriceEnc_UpdateTables(CLenPriceEnc* p, UInt32 numPosStates, UInt32* ProbPrices)
{
    UInt32 posState;
    for (posState = 0; posState < numPosStates; posState++)
        LenPriceEnc_UpdateTable(p, posState, ProbPrices);
}

static void LenEnc_Encode2(CLenPriceEnc* p, CRangeEnc* rc, UInt32 symbol, UInt32 posState, Bool updatePrice, UInt32* ProbPrices)
{
    LenEnc_Encode(&p->p, rc, symbol, posState);
    if (updatePrice)
        if (--p->counters[posState] == 0)
            LenPriceEnc_UpdateTable(p, posState, ProbPrices);
}




static void MovePos(CLzmaEnc* p, UInt32 num)
{
    #ifdef SHOW_STAT
    ttt += num;
    printf("\n MovePos %d", num);
    #endif
    if (num != 0)
    {
        p->additionalOffset += num;
        p->matchFinder.Skip(p->matchFinderObj, num);
    }
}

static UInt32 ReadMatchDistances(CLzmaEnc* p, UInt32* numDistancePairsRes)
{
    UInt32 lenRes = 0, numPairs;
    p->numAvail = p->matchFinder.GetNumAvailableBytes(p->matchFinderObj);
    numPairs = p->matchFinder.GetMatches(p->matchFinderObj, p->matches);
    #ifdef SHOW_STAT
    printf("\n i = %d numPairs = %d    ", ttt, numPairs / 2);
    ttt++;
    {
        UInt32 i;
        for (i = 0; i < numPairs; i += 2)
            printf("%2d %6d   | ", p->matches[i], p->matches[i + 1]);
    }
    #endif
    if (numPairs > 0)
    {
        lenRes = p->matches[numPairs - 2];
        if (lenRes == p->numFastBytes)
        {
            const Byte* pby = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
            UInt32 distance = p->matches[numPairs - 1] + 1;
            UInt32 numAvail = p->numAvail;
            if (numAvail > LZMA_MATCH_LEN_MAX)
                numAvail = LZMA_MATCH_LEN_MAX;
            {
                const Byte* pby2 = pby - distance;
                for (; lenRes < numAvail && pby[lenRes] == pby2[lenRes]; lenRes++) ;
            }
        }
    }
    p->additionalOffset++;
    *numDistancePairsRes = numPairs;
    return lenRes;
}


#define MakeAsChar(p) (p)->backPrev = (UInt32)(-1); (p)->prev1IsChar = False;
#define MakeAsShortRep(p) (p)->backPrev = 0; (p)->prev1IsChar = False;
#define IsShortRep(p) ((p)->backPrev == 0)

static UInt32 GetRepLen1Price(CLzmaEnc* p, UInt32 state, UInt32 posState)
{
    return
        GET_PRICE_0(p->isRepG0[state]) +
        GET_PRICE_0(p->isRep0Long[state][posState]);
}

static UInt32 GetPureRepPrice(CLzmaEnc* p, UInt32 repIndex, UInt32 state, UInt32 posState)
{
    UInt32 price;
    if (repIndex == 0)
    {
        price = GET_PRICE_0(p->isRepG0[state]);
        price += GET_PRICE_1(p->isRep0Long[state][posState]);
    }
    else
    {
        price = GET_PRICE_1(p->isRepG0[state]);
        if (repIndex == 1)
            price += GET_PRICE_0(p->isRepG1[state]);
        else
        {
            price += GET_PRICE_1(p->isRepG1[state]);
            price += GET_PRICE(p->isRepG2[state], repIndex - 2);
        }
    }
    return price;
}

static UInt32 GetRepPrice(CLzmaEnc* p, UInt32 repIndex, UInt32 len, UInt32 state, UInt32 posState)
{
    return p->repLenEnc.prices[posState][len - LZMA_MATCH_LEN_MIN] +
           GetPureRepPrice(p, repIndex, state, posState);
}

static UInt32 Backward(CLzmaEnc* p, UInt32* backRes, UInt32 cur)
{
    UInt32 posMem = p->opt[cur].posPrev;
    UInt32 backMem = p->opt[cur].backPrev;
    p->optimumEndIndex = cur;
    do
    {
        if (p->opt[cur].prev1IsChar)
        {
            MakeAsChar(&p->opt[posMem])
            p->opt[posMem].posPrev = posMem - 1;
            if (p->opt[cur].prev2)
            {
                p->opt[posMem - 1].prev1IsChar = False;
                p->opt[posMem - 1].posPrev = p->opt[cur].posPrev2;
                p->opt[posMem - 1].backPrev = p->opt[cur].backPrev2;
            }
        }
        {
            UInt32 posPrev = posMem;
            UInt32 backCur = backMem;

            backMem = p->opt[posPrev].backPrev;
            posMem = p->opt[posPrev].posPrev;

            p->opt[posPrev].backPrev = backCur;
            p->opt[posPrev].posPrev = cur;
            cur = posPrev;
        }
    }
    while (cur != 0);
    *backRes = p->opt[0].backPrev;
    p->optimumCurrentIndex = p->opt[0].posPrev;
    return p->optimumCurrentIndex;
}

#define LIT_PROBS(pos, prevByte) (p->litProbs + ((((pos) & p->lpMask) << p->lc) + ((prevByte) >> (8 - p->lc))) * 0x300)

static UInt32 GetOptimum(CLzmaEnc* p, UInt32 position, UInt32* backRes)
{
    UInt32 numAvail, mainLen, numPairs, repMaxIndex, i, posState, lenEnd, len, cur;
    UInt32 matchPrice, repMatchPrice, normalMatchPrice;
    UInt32 reps[LZMA_NUM_REPS], repLens[LZMA_NUM_REPS];
    UInt32* matches;
    const Byte* data;
    Byte curByte, matchByte;
    if (p->optimumEndIndex != p->optimumCurrentIndex)
    {
        const COptimal* opt = &p->opt[p->optimumCurrentIndex];
        UInt32 lenRes = opt->posPrev - p->optimumCurrentIndex;
        *backRes = opt->backPrev;
        p->optimumCurrentIndex = opt->posPrev;
        return lenRes;
    }
    p->optimumCurrentIndex = p->optimumEndIndex = 0;

    if (p->additionalOffset == 0)
        mainLen = ReadMatchDistances(p, &numPairs);
    else
    {
        mainLen = p->longestMatchLength;
        numPairs = p->numPairs;
    }

    numAvail = p->numAvail;
    if (numAvail < 2)
    {
        *backRes = (UInt32)(-1);
        return 1;
    }
    if (numAvail > LZMA_MATCH_LEN_MAX)
        numAvail = LZMA_MATCH_LEN_MAX;

    data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
    repMaxIndex = 0;
    for (i = 0; i < LZMA_NUM_REPS; i++)
    {
        UInt32 lenTest;
        const Byte* data2;
        reps[i] = p->reps[i];
        data2 = data - (reps[i] + 1);
        if (data[0] != data2[0] || data[1] != data2[1])
        {
            repLens[i] = 0;
            continue;
        }
        for (lenTest = 2; lenTest < numAvail && data[lenTest] == data2[lenTest]; lenTest++) ;
        repLens[i] = lenTest;
        if (lenTest > repLens[repMaxIndex])
            repMaxIndex = i;
    }
    if (repLens[repMaxIndex] >= p->numFastBytes)
    {
        UInt32 lenRes;
        *backRes = repMaxIndex;
        lenRes = repLens[repMaxIndex];
        MovePos(p, lenRes - 1);
        return lenRes;
    }

    matches = p->matches;
    if (mainLen >= p->numFastBytes)
    {
        *backRes = matches[numPairs - 1] + LZMA_NUM_REPS;
        MovePos(p, mainLen - 1);
        return mainLen;
    }
    curByte = *data;
    matchByte = *(data - (reps[0] + 1));

    if (mainLen < 2 && curByte != matchByte && repLens[repMaxIndex] < 2)
    {
        *backRes = (UInt32) - 1;
        return 1;
    }

    p->opt[0].state = (CState)p->state;

    posState = (position & p->pbMask);

    {
        const CLzmaProb* probs = LIT_PROBS(position, *(data - 1));
        p->opt[1].price = GET_PRICE_0(p->isMatch[p->state][posState]) +
                          (!IsCharState(p->state) ?
                           LitEnc_GetPriceMatched(probs, curByte, matchByte, p->ProbPrices) :
                           LitEnc_GetPrice(probs, curByte, p->ProbPrices));
    }

    MakeAsChar(&p->opt[1]);

    matchPrice = GET_PRICE_1(p->isMatch[p->state][posState]);
    repMatchPrice = matchPrice + GET_PRICE_1(p->isRep[p->state]);

    if (matchByte == curByte)
    {
        UInt32 shortRepPrice = repMatchPrice + GetRepLen1Price(p, p->state, posState);
        if (shortRepPrice < p->opt[1].price)
        {
            p->opt[1].price = shortRepPrice;
            MakeAsShortRep(&p->opt[1]);
        }
    }
    lenEnd = ((mainLen >= repLens[repMaxIndex]) ? mainLen : repLens[repMaxIndex]);

    if (lenEnd < 2)
    {
        *backRes = p->opt[1].backPrev;
        return 1;
    }

    p->opt[1].posPrev = 0;
    for (i = 0; i < LZMA_NUM_REPS; i++)
        p->opt[0].backs[i] = reps[i];

    len = lenEnd;
    do
        p->opt[len--].price = kInfinityPrice;
    while (len >= 2);

    for (i = 0; i < LZMA_NUM_REPS; i++)
    {
        UInt32 repLen = repLens[i];
        UInt32 price;
        if (repLen < 2)
            continue;
        price = repMatchPrice + GetPureRepPrice(p, i, p->state, posState);
        do
        {
            UInt32 curAndLenPrice = price + p->repLenEnc.prices[posState][repLen - 2];
            COptimal* opt = &p->opt[repLen];
            if (curAndLenPrice < opt->price)
            {
                opt->price = curAndLenPrice;
                opt->posPrev = 0;
                opt->backPrev = i;
                opt->prev1IsChar = False;
            }
        }
        while (--repLen >= 2);
    }

    normalMatchPrice = matchPrice + GET_PRICE_0(p->isRep[p->state]);

    len = ((repLens[0] >= 2) ? repLens[0] + 1 : 2);
    if (len <= mainLen)
    {
        UInt32 offs = 0;
        while (len > matches[offs])
            offs += 2;
        for (;; len++)
        {
            COptimal* opt;
            UInt32 distance = matches[offs + 1];

            UInt32 curAndLenPrice = normalMatchPrice + p->lenEnc.prices[posState][len - LZMA_MATCH_LEN_MIN];
            UInt32 lenToPosState = GetLenToPosState(len);
            if (distance < kNumFullDistances)
                curAndLenPrice += p->distancesPrices[lenToPosState][distance];
            else
            {
                UInt32 slot;
                GetPosSlot2(distance, slot);
                curAndLenPrice += p->alignPrices[distance & kAlignMask] + p->posSlotPrices[lenToPosState][slot];
            }
            opt = &p->opt[len];
            if (curAndLenPrice < opt->price)
            {
                opt->price = curAndLenPrice;
                opt->posPrev = 0;
                opt->backPrev = distance + LZMA_NUM_REPS;
                opt->prev1IsChar = False;
            }
            if (len == matches[offs])
            {
                offs += 2;
                if (offs == numPairs)
                    break;
            }
        }
    }

    cur = 0;

    #ifdef SHOW_STAT2
    if (position >= 0)
    {
        unsigned i;
        printf("\n pos = %4X", position);
        for (i = cur; i <= lenEnd; i++)
            printf("\nprice[%4X] = %d", position - cur + i, p->opt[i].price);
    }
    #endif

    for (;;)
    {
        UInt32 numAvailFull, newLen, numPairs, posPrev, state, posState, startLen;
        UInt32 curPrice, curAnd1Price, matchPrice, repMatchPrice;
        Bool nextIsChar;
        Byte curByte, matchByte;
        const Byte* data;
        COptimal* curOpt;
        COptimal* nextOpt;

        cur++;
        if (cur == lenEnd)
            return Backward(p, backRes, cur);

        newLen = ReadMatchDistances(p, &numPairs);
        if (newLen >= p->numFastBytes)
        {
            p->numPairs = numPairs;
            p->longestMatchLength = newLen;
            return Backward(p, backRes, cur);
        }
        position++;
        curOpt = &p->opt[cur];
        posPrev = curOpt->posPrev;
        if (curOpt->prev1IsChar)
        {
            posPrev--;
            if (curOpt->prev2)
            {
                state = p->opt[curOpt->posPrev2].state;
                if (curOpt->backPrev2 < LZMA_NUM_REPS)
                    state = kRepNextStates[state];
                else
                    state = kMatchNextStates[state];
            }
            else
                state = p->opt[posPrev].state;
            state = kLiteralNextStates[state];
        }
        else
            state = p->opt[posPrev].state;
        if (posPrev == cur - 1)
        {
            if (IsShortRep(curOpt))
                state = kShortRepNextStates[state];
            else
                state = kLiteralNextStates[state];
        }
        else
        {
            UInt32 pos;
            const COptimal* prevOpt;
            if (curOpt->prev1IsChar && curOpt->prev2)
            {
                posPrev = curOpt->posPrev2;
                pos = curOpt->backPrev2;
                state = kRepNextStates[state];
            }
            else
            {
                pos = curOpt->backPrev;
                if (pos < LZMA_NUM_REPS)
                    state = kRepNextStates[state];
                else
                    state = kMatchNextStates[state];
            }
            prevOpt = &p->opt[posPrev];
            if (pos < LZMA_NUM_REPS)
            {
                UInt32 i;
                reps[0] = prevOpt->backs[pos];
                for (i = 1; i <= pos; i++)
                    reps[i] = prevOpt->backs[i - 1];
                for (; i < LZMA_NUM_REPS; i++)
                    reps[i] = prevOpt->backs[i];
            }
            else
            {
                UInt32 i;
                reps[0] = (pos - LZMA_NUM_REPS);
                for (i = 1; i < LZMA_NUM_REPS; i++)
                    reps[i] = prevOpt->backs[i - 1];
            }
        }
        curOpt->state = (CState)state;

        curOpt->backs[0] = reps[0];
        curOpt->backs[1] = reps[1];
        curOpt->backs[2] = reps[2];
        curOpt->backs[3] = reps[3];

        curPrice = curOpt->price;
        nextIsChar = False;
        data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
        curByte = *data;
        matchByte = *(data - (reps[0] + 1));

        posState = (position & p->pbMask);

        curAnd1Price = curPrice + GET_PRICE_0(p->isMatch[state][posState]);
        {
            const CLzmaProb* probs = LIT_PROBS(position, *(data - 1));
            curAnd1Price +=
                (!IsCharState(state) ?
                 LitEnc_GetPriceMatched(probs, curByte, matchByte, p->ProbPrices) :
                 LitEnc_GetPrice(probs, curByte, p->ProbPrices));
        }

        nextOpt = &p->opt[cur + 1];

        if (curAnd1Price < nextOpt->price)
        {
            nextOpt->price = curAnd1Price;
            nextOpt->posPrev = cur;
            MakeAsChar(nextOpt);
            nextIsChar = True;
        }

        matchPrice = curPrice + GET_PRICE_1(p->isMatch[state][posState]);
        repMatchPrice = matchPrice + GET_PRICE_1(p->isRep[state]);

        if (matchByte == curByte && !(nextOpt->posPrev < cur && nextOpt->backPrev == 0))
        {
            UInt32 shortRepPrice = repMatchPrice + GetRepLen1Price(p, state, posState);
            if (shortRepPrice <= nextOpt->price)
            {
                nextOpt->price = shortRepPrice;
                nextOpt->posPrev = cur;
                MakeAsShortRep(nextOpt);
                nextIsChar = True;
            }
        }
        numAvailFull = p->numAvail;
        {
            UInt32 temp = kNumOpts - 1 - cur;
            if (temp < numAvailFull)
                numAvailFull = temp;
        }

        if (numAvailFull < 2)
            continue;
        numAvail = (numAvailFull <= p->numFastBytes ? numAvailFull : p->numFastBytes);

        if (!nextIsChar && matchByte != curByte) /* speed optimization */
        {
            /* try Literal + rep0 */
            UInt32 temp;
            UInt32 lenTest2;
            const Byte* data2 = data - (reps[0] + 1);
            UInt32 limit = p->numFastBytes + 1;
            if (limit > numAvailFull)
                limit = numAvailFull;

            for (temp = 1; temp < limit && data[temp] == data2[temp]; temp++) ;
            lenTest2 = temp - 1;
            if (lenTest2 >= 2)
            {
                UInt32 state2 = kLiteralNextStates[state];
                UInt32 posStateNext = (position + 1) & p->pbMask;
                UInt32 nextRepMatchPrice = curAnd1Price +
                                           GET_PRICE_1(p->isMatch[state2][posStateNext]) +
                                           GET_PRICE_1(p->isRep[state2]);
                /* for (; lenTest2 >= 2; lenTest2--) */
                {
                    UInt32 curAndLenPrice;
                    COptimal* opt;
                    UInt32 offset = cur + 1 + lenTest2;
                    while (lenEnd < offset)
                        p->opt[++lenEnd].price = kInfinityPrice;
                    curAndLenPrice = nextRepMatchPrice + GetRepPrice(p, 0, lenTest2, state2, posStateNext);
                    opt = &p->opt[offset];
                    if (curAndLenPrice < opt->price)
                    {
                        opt->price = curAndLenPrice;
                        opt->posPrev = cur + 1;
                        opt->backPrev = 0;
                        opt->prev1IsChar = True;
                        opt->prev2 = False;
                    }
                }
            }
        }

        startLen = 2; /* speed optimization */
        {
            UInt32 repIndex;
            for (repIndex = 0; repIndex < LZMA_NUM_REPS; repIndex++)
            {
                UInt32 lenTest;
                UInt32 lenTestTemp;
                UInt32 price;
                const Byte* data2 = data - (reps[repIndex] + 1);
                if (data[0] != data2[0] || data[1] != data2[1])
                    continue;
                for (lenTest = 2; lenTest < numAvail && data[lenTest] == data2[lenTest]; lenTest++) ;
                while (lenEnd < cur + lenTest)
                    p->opt[++lenEnd].price = kInfinityPrice;
                lenTestTemp = lenTest;
                price = repMatchPrice + GetPureRepPrice(p, repIndex, state, posState);
                do
                {
                    UInt32 curAndLenPrice = price + p->repLenEnc.prices[posState][lenTest - 2];
                    COptimal* opt = &p->opt[cur + lenTest];
                    if (curAndLenPrice < opt->price)
                    {
                        opt->price = curAndLenPrice;
                        opt->posPrev = cur;
                        opt->backPrev = repIndex;
                        opt->prev1IsChar = False;
                    }
                }
                while (--lenTest >= 2);
                lenTest = lenTestTemp;

                if (repIndex == 0)
                    startLen = lenTest + 1;

                /* if (_maxMode) */
                {
                    UInt32 lenTest2 = lenTest + 1;
                    UInt32 limit = lenTest2 + p->numFastBytes;
                    UInt32 nextRepMatchPrice;
                    if (limit > numAvailFull)
                        limit = numAvailFull;
                    for (; lenTest2 < limit && data[lenTest2] == data2[lenTest2]; lenTest2++) ;
                    lenTest2 -= lenTest + 1;
                    if (lenTest2 >= 2)
                    {
                        UInt32 state2 = kRepNextStates[state];
                        UInt32 posStateNext = (position + lenTest) & p->pbMask;
                        UInt32 curAndLenCharPrice =
                            price + p->repLenEnc.prices[posState][lenTest - 2] +
                            GET_PRICE_0(p->isMatch[state2][posStateNext]) +
                            LitEnc_GetPriceMatched(LIT_PROBS(position + lenTest, data[lenTest - 1]),
                                                   data[lenTest], data2[lenTest], p->ProbPrices);
                        state2 = kLiteralNextStates[state2];
                        posStateNext = (position + lenTest + 1) & p->pbMask;
                        nextRepMatchPrice = curAndLenCharPrice +
                                            GET_PRICE_1(p->isMatch[state2][posStateNext]) +
                                            GET_PRICE_1(p->isRep[state2]);

                        /* for (; lenTest2 >= 2; lenTest2--) */
                        {
                            UInt32 curAndLenPrice;
                            COptimal* opt;
                            UInt32 offset = cur + lenTest + 1 + lenTest2;
                            while (lenEnd < offset)
                                p->opt[++lenEnd].price = kInfinityPrice;
                            curAndLenPrice = nextRepMatchPrice + GetRepPrice(p, 0, lenTest2, state2, posStateNext);
                            opt = &p->opt[offset];
                            if (curAndLenPrice < opt->price)
                            {
                                opt->price = curAndLenPrice;
                                opt->posPrev = cur + lenTest + 1;
                                opt->backPrev = 0;
                                opt->prev1IsChar = True;
                                opt->prev2 = True;
                                opt->posPrev2 = cur;
                                opt->backPrev2 = repIndex;
                            }
                        }
                    }
                }
            }
        }
        /* for (UInt32 lenTest = 2; lenTest <= newLen; lenTest++) */
        if (newLen > numAvail)
        {
            newLen = numAvail;
            for (numPairs = 0; newLen > matches[numPairs]; numPairs += 2) ;
            matches[numPairs] = newLen;
            numPairs += 2;
        }
        if (newLen >= startLen)
        {
            UInt32 normalMatchPrice = matchPrice + GET_PRICE_0(p->isRep[state]);
            UInt32 offs, curBack, posSlot;
            UInt32 lenTest;
            while (lenEnd < cur + newLen)
                p->opt[++lenEnd].price = kInfinityPrice;

            offs = 0;
            while (startLen > matches[offs])
                offs += 2;
            curBack = matches[offs + 1];
            GetPosSlot2(curBack, posSlot);
            for (lenTest = /*2*/ startLen;; lenTest++)
            {
                UInt32 curAndLenPrice = normalMatchPrice + p->lenEnc.prices[posState][lenTest - LZMA_MATCH_LEN_MIN];
                UInt32 lenToPosState = GetLenToPosState(lenTest);
                COptimal* opt;
                if (curBack < kNumFullDistances)
                    curAndLenPrice += p->distancesPrices[lenToPosState][curBack];
                else
                    curAndLenPrice += p->posSlotPrices[lenToPosState][posSlot] + p->alignPrices[curBack & kAlignMask];

                opt = &p->opt[cur + lenTest];
                if (curAndLenPrice < opt->price)
                {
                    opt->price = curAndLenPrice;
                    opt->posPrev = cur;
                    opt->backPrev = curBack + LZMA_NUM_REPS;
                    opt->prev1IsChar = False;
                }

                if (/*_maxMode && */ lenTest == matches[offs])
                {
                    /* Try Match + Literal + Rep0 */
                    const Byte* data2 = data - (curBack + 1);
                    UInt32 lenTest2 = lenTest + 1;
                    UInt32 limit = lenTest2 + p->numFastBytes;
                    UInt32 nextRepMatchPrice;
                    if (limit > numAvailFull)
                        limit = numAvailFull;
                    for (; lenTest2 < limit && data[lenTest2] == data2[lenTest2]; lenTest2++) ;
                    lenTest2 -= lenTest + 1;
                    if (lenTest2 >= 2)
                    {
                        UInt32 state2 = kMatchNextStates[state];
                        UInt32 posStateNext = (position + lenTest) & p->pbMask;
                        UInt32 curAndLenCharPrice = curAndLenPrice +
                                                    GET_PRICE_0(p->isMatch[state2][posStateNext]) +
                                                    LitEnc_GetPriceMatched(LIT_PROBS(position + lenTest, data[lenTest - 1]),
                                                                           data[lenTest], data2[lenTest], p->ProbPrices);
                        state2 = kLiteralNextStates[state2];
                        posStateNext = (posStateNext + 1) & p->pbMask;
                        nextRepMatchPrice = curAndLenCharPrice +
                                            GET_PRICE_1(p->isMatch[state2][posStateNext]) +
                                            GET_PRICE_1(p->isRep[state2]);

                        /* for (; lenTest2 >= 2; lenTest2--) */
                        {
                            UInt32 offset = cur + lenTest + 1 + lenTest2;
                            UInt32 curAndLenPrice;
                            COptimal* opt;
                            while (lenEnd < offset)
                                p->opt[++lenEnd].price = kInfinityPrice;
                            curAndLenPrice = nextRepMatchPrice + GetRepPrice(p, 0, lenTest2, state2, posStateNext);
                            opt = &p->opt[offset];
                            if (curAndLenPrice < opt->price)
                            {
                                opt->price = curAndLenPrice;
                                opt->posPrev = cur + lenTest + 1;
                                opt->backPrev = 0;
                                opt->prev1IsChar = True;
                                opt->prev2 = True;
                                opt->posPrev2 = cur;
                                opt->backPrev2 = curBack + LZMA_NUM_REPS;
                            }
                        }
                    }
                    offs += 2;
                    if (offs == numPairs)
                        break;
                    curBack = matches[offs + 1];
                    if (curBack >= kNumFullDistances)
                        GetPosSlot2(curBack, posSlot);
                }
            }
        }
    }
}

#define ChangePair(smallDist, bigDist) (((bigDist) >> 7) > (smallDist))

static UInt32 GetOptimumFast(CLzmaEnc* p, UInt32* backRes)
{
    UInt32 numAvail, mainLen, mainDist, numPairs, repIndex, repLen, i;
    const Byte* data;
    const UInt32* matches;

    if (p->additionalOffset == 0)
        mainLen = ReadMatchDistances(p, &numPairs);
    else
    {
        mainLen = p->longestMatchLength;
        numPairs = p->numPairs;
    }

    numAvail = p->numAvail;
    *backRes = (UInt32) - 1;
    if (numAvail < 2)
        return 1;
    if (numAvail > LZMA_MATCH_LEN_MAX)
        numAvail = LZMA_MATCH_LEN_MAX;
    data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;

    repLen = repIndex = 0;
    for (i = 0; i < LZMA_NUM_REPS; i++)
    {
        UInt32 len;
        const Byte* data2 = data - (p->reps[i] + 1);
        if (data[0] != data2[0] || data[1] != data2[1])
            continue;
        for (len = 2; len < numAvail && data[len] == data2[len]; len++) ;
        if (len >= p->numFastBytes)
        {
            *backRes = i;
            MovePos(p, len - 1);
            return len;
        }
        if (len > repLen)
        {
            repIndex = i;
            repLen = len;
        }
    }

    matches = p->matches;
    if (mainLen >= p->numFastBytes)
    {
        *backRes = matches[numPairs - 1] + LZMA_NUM_REPS;
        MovePos(p, mainLen - 1);
        return mainLen;
    }

    mainDist = 0; /* for GCC */
    if (mainLen >= 2)
    {
        mainDist = matches[numPairs - 1];
        while (numPairs > 2 && mainLen == matches[numPairs - 4] + 1)
        {
            if (!ChangePair(matches[numPairs - 3], mainDist))
                break;
            numPairs -= 2;
            mainLen = matches[numPairs - 2];
            mainDist = matches[numPairs - 1];
        }
        if (mainLen == 2 && mainDist >= 0x80)
            mainLen = 1;
    }

    if (repLen >= 2 && (
            (repLen + 1 >= mainLen) ||
            (repLen + 2 >= mainLen && mainDist >= (1 << 9)) ||
            (repLen + 3 >= mainLen && mainDist >= (1 << 15))))
    {
        *backRes = repIndex;
        MovePos(p, repLen - 1);
        return repLen;
    }

    if (mainLen < 2 || numAvail <= 2)
        return 1;

    p->longestMatchLength = ReadMatchDistances(p, &p->numPairs);
    if (p->longestMatchLength >= 2)
    {
        UInt32 newDistance = matches[p->numPairs - 1];
        if ((p->longestMatchLength >= mainLen && newDistance < mainDist) ||
            (p->longestMatchLength == mainLen + 1 && !ChangePair(mainDist, newDistance)) ||
            (p->longestMatchLength > mainLen + 1) ||
            (p->longestMatchLength + 1 >= mainLen && mainLen >= 3 && ChangePair(newDistance, mainDist)))
            return 1;
    }

    data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - 1;
    for (i = 0; i < LZMA_NUM_REPS; i++)
    {
        UInt32 len, limit;
        const Byte* data2 = data - (p->reps[i] + 1);
        if (data[0] != data2[0] || data[1] != data2[1])
            continue;
        limit = mainLen - 1;
        for (len = 2; len < limit && data[len] == data2[len]; len++) ;
        if (len >= limit)
            return 1;
    }
    *backRes = mainDist + LZMA_NUM_REPS;
    MovePos(p, mainLen - 2);
    return mainLen;
}

static void WriteEndMarker(CLzmaEnc* p, UInt32 posState)
{
    UInt32 len;
    RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][posState], 1);
    RangeEnc_EncodeBit(&p->rc, &p->isRep[p->state], 0);
    p->state = kMatchNextStates[p->state];
    len = LZMA_MATCH_LEN_MIN;
    LenEnc_Encode2(&p->lenEnc, &p->rc, len - LZMA_MATCH_LEN_MIN, posState, !p->fastMode, p->ProbPrices);
    RcTree_Encode(&p->rc, p->posSlotEncoder[GetLenToPosState(len)], kNumPosSlotBits, (1 << kNumPosSlotBits) - 1);
    RangeEnc_EncodeDirectBits(&p->rc, (((UInt32)1 << 30) - 1) >> kNumAlignBits, 30 - kNumAlignBits);
    RcTree_ReverseEncode(&p->rc, p->posAlignEncoder, kNumAlignBits, kAlignMask);
}

static SRes CheckErrors(CLzmaEnc* p)
{
    if (p->result != SZ_OK)
        return p->result;
    if (p->rc.res != SZ_OK)
        p->result = SZ_ERROR_WRITE;
    if (p->matchFinderBase.result != SZ_OK)
        p->result = SZ_ERROR_READ;
    if (p->result != SZ_OK)
        p->finished = True;
    return p->result;
}

static SRes Flush(CLzmaEnc* p, UInt32 nowPos)
{
    /* ReleaseMFStream(); */
    p->finished = True;
    if (p->writeEndMark)
        WriteEndMarker(p, nowPos & p->pbMask);
    RangeEnc_FlushData(&p->rc);
    RangeEnc_FlushStream(&p->rc);
    return CheckErrors(p);
}

static void FillAlignPrices(CLzmaEnc* p)
{
    UInt32 i;
    for (i = 0; i < kAlignTableSize; i++)
        p->alignPrices[i] = RcTree_ReverseGetPrice(p->posAlignEncoder, kNumAlignBits, i, p->ProbPrices);
    p->alignPriceCount = 0;
}

static void FillDistancesPrices(CLzmaEnc* p)
{
    UInt32 tempPrices[kNumFullDistances];
    UInt32 i, lenToPosState;
    for (i = kStartPosModelIndex; i < kNumFullDistances; i++)
    {
        UInt32 posSlot = GetPosSlot1(i);
        UInt32 footerBits = ((posSlot >> 1) - 1);
        UInt32 base = ((2 | (posSlot & 1)) << footerBits);
        tempPrices[i] = RcTree_ReverseGetPrice(p->posEncoders + base - posSlot - 1, footerBits, i - base, p->ProbPrices);
    }

    for (lenToPosState = 0; lenToPosState < kNumLenToPosStates; lenToPosState++)
    {
        UInt32 posSlot;
        const CLzmaProb* encoder = p->posSlotEncoder[lenToPosState];
        UInt32* posSlotPrices = p->posSlotPrices[lenToPosState];
        for (posSlot = 0; posSlot < p->distTableSize; posSlot++)
            posSlotPrices[posSlot] = RcTree_GetPrice(encoder, kNumPosSlotBits, posSlot, p->ProbPrices);
        for (posSlot = kEndPosModelIndex; posSlot < p->distTableSize; posSlot++)
            posSlotPrices[posSlot] += ((((posSlot >> 1) - 1) - kNumAlignBits) << kNumBitPriceShiftBits);

        {
            UInt32* distancesPrices = p->distancesPrices[lenToPosState];
            UInt32 i;
            for (i = 0; i < kStartPosModelIndex; i++)
                distancesPrices[i] = posSlotPrices[i];
            for (; i < kNumFullDistances; i++)
                distancesPrices[i] = posSlotPrices[GetPosSlot1(i)] + tempPrices[i];
        }
    }
    p->matchPriceCount = 0;
}

void LzmaEnc_Construct(CLzmaEnc* p)
{
    RangeEnc_Construct(&p->rc);
    MatchFinder_Construct(&p->matchFinderBase);
    #ifndef _7ZIP_ST
    MatchFinderMt_Construct(&p->matchFinderMt);
    p->matchFinderMt.MatchFinder = &p->matchFinderBase;
    #endif

    {
        CLzmaEncProps props;
        LzmaEncProps_Init(&props);
        LzmaEnc_SetProps(p, &props);
    }

    #ifndef LZMA_LOG_BSR
    LzmaEnc_FastPosInit(p->g_FastPos);
    #endif

    LzmaEnc_InitPriceTables(p->ProbPrices);
    p->litProbs = 0;
    p->saveState.litProbs = 0;
}

CLzmaEncHandle LzmaEnc_Create(ISzAlloc* alloc)
{
    void* p;
    p = alloc->Alloc(alloc, sizeof(CLzmaEnc));
    if (p != 0)
        LzmaEnc_Construct((CLzmaEnc*)p);
    return p;
}

void LzmaEnc_FreeLits(CLzmaEnc* p, ISzAlloc* alloc)
{
    alloc->Free(alloc, p->litProbs);
    alloc->Free(alloc, p->saveState.litProbs);
    p->litProbs = 0;
    p->saveState.litProbs = 0;
}

void LzmaEnc_Destruct(CLzmaEnc* p, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    #ifndef _7ZIP_ST
    MatchFinderMt_Destruct(&p->matchFinderMt, allocBig);
    #endif
    MatchFinder_Free(&p->matchFinderBase, allocBig);
    LzmaEnc_FreeLits(p, alloc);
    RangeEnc_Free(&p->rc, alloc);
}

void LzmaEnc_Destroy(CLzmaEncHandle p, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    LzmaEnc_Destruct((CLzmaEnc*)p, alloc, allocBig);
    alloc->Free(alloc, p);
}

static SRes LzmaEnc_CodeOneBlock(CLzmaEnc* p, Bool useLimits, UInt32 maxPackSize, UInt32 maxUnpackSize)
{
    UInt32 nowPos32, startPos32;
    if (p->needInit)
    {
        p->matchFinder.Init(p->matchFinderObj);
        p->needInit = 0;
    }

    if (p->finished)
        return p->result;
    RINOK(CheckErrors(p));

    nowPos32 = (UInt32)p->nowPos64;
    startPos32 = nowPos32;

    if (p->nowPos64 == 0)
    {
        UInt32 numPairs;
        Byte curByte;
        if (p->matchFinder.GetNumAvailableBytes(p->matchFinderObj) == 0)
            return Flush(p, nowPos32);
        ReadMatchDistances(p, &numPairs);
        RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][0], 0);
        p->state = kLiteralNextStates[p->state];
        curByte = p->matchFinder.GetIndexByte(p->matchFinderObj, 0 - p->additionalOffset);
        LitEnc_Encode(&p->rc, p->litProbs, curByte);
        p->additionalOffset--;
        nowPos32++;
    }

    if (p->matchFinder.GetNumAvailableBytes(p->matchFinderObj) != 0)
        for (;;)
        {
            UInt32 pos, len, posState;

            if (p->fastMode)
                len = GetOptimumFast(p, &pos);
            else
                len = GetOptimum(p, nowPos32, &pos);

            #ifdef SHOW_STAT2
            printf("\n pos = %4X,   len = %d   pos = %d", nowPos32, len, pos);
            #endif

            posState = nowPos32 & p->pbMask;
            if (len == 1 && pos == (UInt32) - 1)
            {
                Byte curByte;
                CLzmaProb* probs;
                const Byte* data;

                RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][posState], 0);
                data = p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - p->additionalOffset;
                curByte = *data;
                probs = LIT_PROBS(nowPos32, *(data - 1));
                if (IsCharState(p->state))
                    LitEnc_Encode(&p->rc, probs, curByte);
                else
                    LitEnc_EncodeMatched(&p->rc, probs, curByte, *(data - p->reps[0] - 1));
                p->state = kLiteralNextStates[p->state];
            }
            else
            {
                RangeEnc_EncodeBit(&p->rc, &p->isMatch[p->state][posState], 1);
                if (pos < LZMA_NUM_REPS)
                {
                    RangeEnc_EncodeBit(&p->rc, &p->isRep[p->state], 1);
                    if (pos == 0)
                    {
                        RangeEnc_EncodeBit(&p->rc, &p->isRepG0[p->state], 0);
                        RangeEnc_EncodeBit(&p->rc, &p->isRep0Long[p->state][posState], ((len == 1) ? 0 : 1));
                    }
                    else
                    {
                        UInt32 distance = p->reps[pos];
                        RangeEnc_EncodeBit(&p->rc, &p->isRepG0[p->state], 1);
                        if (pos == 1)
                            RangeEnc_EncodeBit(&p->rc, &p->isRepG1[p->state], 0);
                        else
                        {
                            RangeEnc_EncodeBit(&p->rc, &p->isRepG1[p->state], 1);
                            RangeEnc_EncodeBit(&p->rc, &p->isRepG2[p->state], pos - 2);
                            if (pos == 3)
                                p->reps[3] = p->reps[2];
                            p->reps[2] = p->reps[1];
                        }
                        p->reps[1] = p->reps[0];
                        p->reps[0] = distance;
                    }
                    if (len == 1)
                        p->state = kShortRepNextStates[p->state];
                    else
                    {
                        LenEnc_Encode2(&p->repLenEnc, &p->rc, len - LZMA_MATCH_LEN_MIN, posState, !p->fastMode, p->ProbPrices);
                        p->state = kRepNextStates[p->state];
                    }
                }
                else
                {
                    UInt32 posSlot;
                    RangeEnc_EncodeBit(&p->rc, &p->isRep[p->state], 0);
                    p->state = kMatchNextStates[p->state];
                    LenEnc_Encode2(&p->lenEnc, &p->rc, len - LZMA_MATCH_LEN_MIN, posState, !p->fastMode, p->ProbPrices);
                    pos -= LZMA_NUM_REPS;
                    GetPosSlot(pos, posSlot);
                    RcTree_Encode(&p->rc, p->posSlotEncoder[GetLenToPosState(len)], kNumPosSlotBits, posSlot);

                    if (posSlot >= kStartPosModelIndex)
                    {
                        UInt32 footerBits = ((posSlot >> 1) - 1);
                        UInt32 base = ((2 | (posSlot & 1)) << footerBits);
                        UInt32 posReduced = pos - base;

                        if (posSlot < kEndPosModelIndex)
                            RcTree_ReverseEncode(&p->rc, p->posEncoders + base - posSlot - 1, footerBits, posReduced);
                        else
                        {
                            RangeEnc_EncodeDirectBits(&p->rc, posReduced >> kNumAlignBits, footerBits - kNumAlignBits);
                            RcTree_ReverseEncode(&p->rc, p->posAlignEncoder, kNumAlignBits, posReduced & kAlignMask);
                            p->alignPriceCount++;
                        }
                    }
                    p->reps[3] = p->reps[2];
                    p->reps[2] = p->reps[1];
                    p->reps[1] = p->reps[0];
                    p->reps[0] = pos;
                    p->matchPriceCount++;
                }
            }
            p->additionalOffset -= len;
            nowPos32 += len;
            if (p->additionalOffset == 0)
            {
                UInt32 processed;
                if (!p->fastMode)
                {
                    if (p->matchPriceCount >= (1 << 7))
                        FillDistancesPrices(p);
                    if (p->alignPriceCount >= kAlignTableSize)
                        FillAlignPrices(p);
                }
                if (p->matchFinder.GetNumAvailableBytes(p->matchFinderObj) == 0)
                    break;
                processed = nowPos32 - startPos32;
                if (useLimits)
                {
                    if (processed + kNumOpts + 300 >= maxUnpackSize ||
                        RangeEnc_GetProcessed(&p->rc) + kNumOpts * 2 >= maxPackSize)
                        break;
                }
                else if (processed >= (1 << 15))
                {
                    p->nowPos64 += nowPos32 - startPos32;
                    return CheckErrors(p);
                }
            }
        }
    p->nowPos64 += nowPos32 - startPos32;
    return Flush(p, nowPos32);
}

#define kBigHashDicLimit ((UInt32)1 << 24)

static SRes LzmaEnc_Alloc(CLzmaEnc* p, UInt32 keepWindowSize, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    UInt32 beforeSize = kNumOpts;
    Bool btMode;
    if (!RangeEnc_Alloc(&p->rc, alloc))
        return SZ_ERROR_MEM;
    btMode = (p->matchFinderBase.btMode != 0);
    #ifndef _7ZIP_ST
    p->mtMode = (p->multiThread && !p->fastMode && btMode);
    #endif

    {
        unsigned lclp = p->lc + p->lp;
        if (p->litProbs == 0 || p->saveState.litProbs == 0 || p->lclp != lclp)
        {
            LzmaEnc_FreeLits(p, alloc);
            p->litProbs = (CLzmaProb*)alloc->Alloc(alloc, (0x300 << lclp) * sizeof(CLzmaProb));
            p->saveState.litProbs = (CLzmaProb*)alloc->Alloc(alloc, (0x300 << lclp) * sizeof(CLzmaProb));
            if (p->litProbs == 0 || p->saveState.litProbs == 0)
            {
                LzmaEnc_FreeLits(p, alloc);
                return SZ_ERROR_MEM;
            }
            p->lclp = lclp;
        }
    }

    p->matchFinderBase.bigHash = (p->dictSize > kBigHashDicLimit);

    if (beforeSize + p->dictSize < keepWindowSize)
        beforeSize = keepWindowSize - p->dictSize;

    #ifndef _7ZIP_ST
    if (p->mtMode)
    {
        RINOK(MatchFinderMt_Create(&p->matchFinderMt, p->dictSize, beforeSize, p->numFastBytes, LZMA_MATCH_LEN_MAX, allocBig));
        p->matchFinderObj = &p->matchFinderMt;
        MatchFinderMt_CreateVTable(&p->matchFinderMt, &p->matchFinder);
    }
    else
    #endif
    {
        if (!MatchFinder_Create(&p->matchFinderBase, p->dictSize, beforeSize, p->numFastBytes, LZMA_MATCH_LEN_MAX, allocBig))
            return SZ_ERROR_MEM;
        p->matchFinderObj = &p->matchFinderBase;
        MatchFinder_CreateVTable(&p->matchFinderBase, &p->matchFinder);
    }
    return SZ_OK;
}

void LzmaEnc_Init(CLzmaEnc* p)
{
    UInt32 i;
    p->state = 0;
    for (i = 0; i < LZMA_NUM_REPS; i++)
        p->reps[i] = 0;

    RangeEnc_Init(&p->rc);


    for (i = 0; i < kNumStates; i++)
    {
        UInt32 j;
        for (j = 0; j < LZMA_NUM_PB_STATES_MAX; j++)
        {
            p->isMatch[i][j] = kProbInitValue;
            p->isRep0Long[i][j] = kProbInitValue;
        }
        p->isRep[i] = kProbInitValue;
        p->isRepG0[i] = kProbInitValue;
        p->isRepG1[i] = kProbInitValue;
        p->isRepG2[i] = kProbInitValue;
    }

    {
        UInt32 num = 0x300 << (p->lp + p->lc);
        for (i = 0; i < num; i++)
            p->litProbs[i] = kProbInitValue;
    }

    {
        for (i = 0; i < kNumLenToPosStates; i++)
        {
            CLzmaProb* probs = p->posSlotEncoder[i];
            UInt32 j;
            for (j = 0; j < (1 << kNumPosSlotBits); j++)
                probs[j] = kProbInitValue;
        }
    }
    {
        for (i = 0; i < kNumFullDistances - kEndPosModelIndex; i++)
            p->posEncoders[i] = kProbInitValue;
    }

    LenEnc_Init(&p->lenEnc.p);
    LenEnc_Init(&p->repLenEnc.p);

    for (i = 0; i < (1 << kNumAlignBits); i++)
        p->posAlignEncoder[i] = kProbInitValue;

    p->optimumEndIndex = 0;
    p->optimumCurrentIndex = 0;
    p->additionalOffset = 0;

    p->pbMask = (1 << p->pb) - 1;
    p->lpMask = (1 << p->lp) - 1;
}

void LzmaEnc_InitPrices(CLzmaEnc* p)
{
    if (!p->fastMode)
    {
        FillDistancesPrices(p);
        FillAlignPrices(p);
    }

    p->lenEnc.tableSize =
        p->repLenEnc.tableSize =
            p->numFastBytes + 1 - LZMA_MATCH_LEN_MIN;
    LenPriceEnc_UpdateTables(&p->lenEnc, 1 << p->pb, p->ProbPrices);
    LenPriceEnc_UpdateTables(&p->repLenEnc, 1 << p->pb, p->ProbPrices);
}

static SRes LzmaEnc_AllocAndInit(CLzmaEnc* p, UInt32 keepWindowSize, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    UInt32 i;
    for (i = 0; i < (UInt32)kDicLogSizeMaxCompress; i++)
        if (p->dictSize <= ((UInt32)1 << i))
            break;
    p->distTableSize = i * 2;

    p->finished = False;
    p->result = SZ_OK;
    RINOK(LzmaEnc_Alloc(p, keepWindowSize, alloc, allocBig));
    LzmaEnc_Init(p);
    LzmaEnc_InitPrices(p);
    p->nowPos64 = 0;
    return SZ_OK;
}

static SRes LzmaEnc_Prepare(CLzmaEncHandle pp, ISeqOutStream* outStream, ISeqInStream* inStream,
                            ISzAlloc* alloc, ISzAlloc* allocBig)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    p->matchFinderBase.stream = inStream;
    p->needInit = 1;
    p->rc.outStream = outStream;
    return LzmaEnc_AllocAndInit(p, 0, alloc, allocBig);
}

SRes LzmaEnc_PrepareForLzma2(CLzmaEncHandle pp,
                             ISeqInStream* inStream, UInt32 keepWindowSize,
                             ISzAlloc* alloc, ISzAlloc* allocBig)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    p->matchFinderBase.stream = inStream;
    p->needInit = 1;
    return LzmaEnc_AllocAndInit(p, keepWindowSize, alloc, allocBig);
}

static void LzmaEnc_SetInputBuf(CLzmaEnc* p, const Byte* src, SizeT srcLen)
{
    p->matchFinderBase.directInput = 1;
    p->matchFinderBase.bufferBase = (Byte*)src;
    p->matchFinderBase.directInputRem = srcLen;
}

SRes LzmaEnc_MemPrepare(CLzmaEncHandle pp, const Byte* src, SizeT srcLen,
                        UInt32 keepWindowSize, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    LzmaEnc_SetInputBuf(p, src, srcLen);
    p->needInit = 1;

    return LzmaEnc_AllocAndInit(p, keepWindowSize, alloc, allocBig);
}

void LzmaEnc_Finish(CLzmaEncHandle pp)
{
    #ifndef _7ZIP_ST
    CLzmaEnc* p = (CLzmaEnc*)pp;
    if (p->mtMode)
        MatchFinderMt_ReleaseStream(&p->matchFinderMt);
    #else
    pp = pp;
    #endif
}

typedef struct
{
    ISeqOutStream funcTable;
    Byte* data;
    SizeT rem;
    Bool overflow;
} CSeqOutStreamBuf;

static size_t MyWrite(void* pp, const void* data, size_t size)
{
    CSeqOutStreamBuf* p = (CSeqOutStreamBuf*)pp;
    if (p->rem < size)
    {
        size = p->rem;
        p->overflow = True;
    }
    memcpy(p->data, data, size);
    p->rem -= size;
    p->data += size;
    return size;
}


UInt32 LzmaEnc_GetNumAvailableBytes(CLzmaEncHandle pp)
{
    const CLzmaEnc* p = (CLzmaEnc*)pp;
    return p->matchFinder.GetNumAvailableBytes(p->matchFinderObj);
}

const Byte * LzmaEnc_GetCurBuf(CLzmaEncHandle pp)
{
    const CLzmaEnc* p = (CLzmaEnc*)pp;
    return p->matchFinder.GetPointerToCurrentPos(p->matchFinderObj) - p->additionalOffset;
}

SRes LzmaEnc_CodeOneMemBlock(CLzmaEncHandle pp, Bool reInit,
                             Byte* dest, size_t* destLen, UInt32 desiredPackSize, UInt32* unpackSize)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    UInt64 nowPos64;
    SRes res;
    CSeqOutStreamBuf outStream;

    outStream.funcTable.Write = MyWrite;
    outStream.data = dest;
    outStream.rem = *destLen;
    outStream.overflow = False;

    p->writeEndMark = False;
    p->finished = False;
    p->result = SZ_OK;

    if (reInit)
        LzmaEnc_Init(p);
    LzmaEnc_InitPrices(p);
    nowPos64 = p->nowPos64;
    RangeEnc_Init(&p->rc);
    p->rc.outStream = &outStream.funcTable;

    res = LzmaEnc_CodeOneBlock(p, True, desiredPackSize, *unpackSize);

    *unpackSize = (UInt32)(p->nowPos64 - nowPos64);
    *destLen -= outStream.rem;
    if (outStream.overflow)
        return SZ_ERROR_OUTPUT_EOF;

    return res;
}

static SRes LzmaEnc_Encode2(CLzmaEnc* p, ICompressProgress* progress)
{
    SRes res = SZ_OK;

    #ifndef _7ZIP_ST
    Byte allocaDummy[0x300];
    int i = 0;
    for (i = 0; i < 16; i++)
        allocaDummy[i] = (Byte)i;
    #endif

    for (;;)
    {
        res = LzmaEnc_CodeOneBlock(p, False, 0, 0);
        if (res != SZ_OK || p->finished != 0)
            break;
        if (progress != 0)
        {
            res = progress->Progress(progress, p->nowPos64, RangeEnc_GetProcessed(&p->rc));
            if (res != SZ_OK)
            {
                res = SZ_ERROR_PROGRESS;
                break;
            }
        }
    }
    LzmaEnc_Finish(p);
    return res;
}

SRes LzmaEnc_Encode(CLzmaEncHandle pp, ISeqOutStream* outStream, ISeqInStream* inStream, ICompressProgress* progress,
                    ISzAlloc* alloc, ISzAlloc* allocBig)
{
    RINOK(LzmaEnc_Prepare(pp, outStream, inStream, alloc, allocBig));
    return LzmaEnc_Encode2((CLzmaEnc*)pp, progress);
}

SRes LzmaEnc_WriteProperties(CLzmaEncHandle pp, Byte* props, SizeT* size)
{
    CLzmaEnc* p = (CLzmaEnc*)pp;
    int i;
    UInt32 dictSize = p->dictSize;
    if (*size < LZMA_PROPS_SIZE)
        return SZ_ERROR_PARAM;
    *size = LZMA_PROPS_SIZE;
    props[0] = (Byte)((p->pb * 5 + p->lp) * 9 + p->lc);

    for (i = 11; i <= 30; i++)
    {
        if (dictSize <= ((UInt32)2 << i))
        {
            dictSize = (2 << i);
            break;
        }
        if (dictSize <= ((UInt32)3 << i))
        {
            dictSize = (3 << i);
            break;
        }
    }

    for (i = 0; i < 4; i++)
        props[1 + i] = (Byte)(dictSize >> (8 * i));
    return SZ_OK;
}

SRes LzmaEnc_MemEncode(CLzmaEncHandle pp, Byte* dest, SizeT* destLen, const Byte* src, SizeT srcLen,
                       int writeEndMark, ICompressProgress* progress, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    SRes res;
    CLzmaEnc* p = (CLzmaEnc*)pp;

    CSeqOutStreamBuf outStream;

    LzmaEnc_SetInputBuf(p, src, srcLen);

    outStream.funcTable.Write = MyWrite;
    outStream.data = dest;
    outStream.rem = *destLen;
    outStream.overflow = False;

    p->writeEndMark = writeEndMark;

    p->rc.outStream = &outStream.funcTable;
    res = LzmaEnc_MemPrepare(pp, src, srcLen, 0, alloc, allocBig);
    if (res == SZ_OK)
        res = LzmaEnc_Encode2(p, progress);

    *destLen -= outStream.rem;
    if (outStream.overflow)
        return SZ_ERROR_OUTPUT_EOF;
    return res;
}

SRes LzmaEncode(Byte* dest, SizeT* destLen, const Byte* src, SizeT srcLen,
                const CLzmaEncProps* props, Byte* propsEncoded, SizeT* propsSize, int writeEndMark,
                ICompressProgress* progress, ISzAlloc* alloc, ISzAlloc* allocBig)
{
    CLzmaEnc* p = (CLzmaEnc*)LzmaEnc_Create(alloc);
    SRes res;
    if (p == 0)
        return SZ_ERROR_MEM;

    res = LzmaEnc_SetProps(p, props);
    if (res == SZ_OK)
    {
        res = LzmaEnc_WriteProperties(p, propsEncoded, propsSize);
        if (res == SZ_OK)
            res = LzmaEnc_MemEncode(p, dest, destLen, src, srcLen,
                                    writeEndMark, progress, alloc, allocBig);
    }

    LzmaEnc_Destroy(p, alloc, allocBig);
    return res;
}